DE2201875B2 - Method and device for the reproduction of algae - Google Patents

Description

The invention relates to a method for propagating algae as additional feed for livestock, with excrement decomposed in the presence of oxygen and then fed to the algae, and a device to carry out this procedure.

From US-PS 35 46 812 such a method is 5 <> known, in which excrement is fed from a storage container via a drum screen to an aerator be where at a temperature of 35 to 39 "C air is blown in while stirring the excrement. The contents of this container are then transferred to a sterilization tank, fed to a precipitator and a filter; then the remaining, partially decomposed liquid supplied to containers for aerobic decomposition. Then the increased aerobic bacteria are drawn off and the liquid is fed into an open algae reproduction tank. In A downstream centrifuge separates the wastewater and the increased algae. This well-known Large system has the disadvantage that it is much too expensive for use as a small system by the animal keeper is.

In the case of mass feeding, especially of stable cattle, it has been shown that the feed used is due to often long storage or transport times shows changes in the microbiological area that lead to it that the cattle are suffering from deficiency symptoms Need to prepare the manure in such a way that it is odorless. Related processing procedures have already become known.

The invention is based on the object of developing a method of the type described at the outset so that that there is little structural effort in the system intended for its implementation and little Energy expenditure can also be used directly by the animal owner in temperate zones.

This object is inventively achieved in that which is heated by the aerobic oxidation of 60 to 70 ⁰ C is used as the excrement Schwemmist, and that the thermal energy generated is used to control the temperature of the algae medium.

With the invention is therefore made possible that practically in the cycle the excrement of the animals to one high-quality additional feeders can be processed. It is hereby possible, directly at the stables Alluvial water is to be processed in such a way that it is odor-free on the one hand, which eliminates the unpleasant smell that would otherwise occur the environment is prevented, and that on the other hand;) removal problems of the processed Scbwemmistes are largely eliminated, while at the same time valuable additional feed is created for the animals to compensate for deficiency symptoms and as high-quality protein feed. F.s It has been shown that with the use of alluvial dung, the consistently a largely similar composition The algae drinker that is present after the algae has multiplied has settled directly without further processing can be fed back to the animals as feed. By heating up the manure at the aerobic oxidation occurs in addition to an optimal acceleration of the oxidation process, which leads to a minimal Residence time of alluvial manure and thus a minimal size of the required containers, a killing of practically all pathogenic germs and worm eggs, so that a subsequent sterilization not * necessary. In addition, in the temperate zones there is generally a feeder even in winter of expensive heating energy in the circuit is not necessary.

Advantageously, what is formed during the decomposition CO2 is supplied to the algae in gaseous form, which significantly stimulates the algae to multiply.

According to the invention, in a system for carrying out the method according to the invention in or on a container for the decomposition of the flood and in or on an algae reproductive tank heat exchangers coupled to one another to form a heat circuit are arranged, with the regulation of the Temperature in the algae reproduction basin and thus to control the heat flow from the container to the algae reproduction basin a thermostat is provided, and the container is provided with thermal insulation. These measures serve to achieve the abovementioned advantages of the method according to the invention.

The algae reproduction basin is also advantageously thermally insulated. It is also advantageous if the container is covered and a line for transferring the CO2 produced during the decomposition is intended for the algae reproduction tank.

Furthermore, it can be advantageous if the Al-

genreproduction tank a device for separating Substances not absorbed by the algae from the algae drinker are downstream, for example a centrifuge is suitable As tests have shown, this is usually not necessary.

Further advantages and features of the invention result from the description of the embodiment example based on the drawing. In the drawing shows

F i g. 1 is a schematic representation of a complete system for the reproduction of algae and F i g. 2 an aolche plant in longitudinal section

From a stable 1, the excrement of the animals that accumulates there is removed by an or with the addition of water several Schwemmislkamäle 2 as alluvial is a collecting basin 3, which is regularly outside the stable I is arranged and can be sunk in the ground, fed. The stall air is sucked out of the stall and also cleaned by means of water in an exhaust air scrubber 4, the suspended matter contained in the stable air be absorbed by the water. The cleaned air is released into the atmosphere and the cleaning water can also be fed to the collecting basin 3 via a line 5.

The floating dung is removed from the closed collecting basin 3 by means of a pump 6 via a line 7 pumped to a container 8. This container 8 is essentially closed on all sides and has an agitator 9, by means of which air sucked in through a ventilation 10 in the container lid into the floating dung is stirred in. The air is expediently supplied through a hollow shaft 11 of the agitator 9, so that the sucked in air is fed directly to the floating dung without being previously in the free space above the manure level.

The alluvial dung is decomposed by the oxygen in the air and the aerobic bacteria contained in the air, whereby COi, H2O, NOj, SO4 and PO4 are mainly produced. In addition, heat is generated and the aerobic bacteria multiply.

The container 8 is followed by an algae multiplication basin 12. In this algae breeding basin the practically odor-free liquid that forms after the aerobic decomposition of the manure is transferred a line 13 is supplied. In addition, the CO2 produced during the decomposition, the 'as-shaped in the Space above the alluvial manure in container 8 collects, fed via a line 14 to the algae multiplication basin, this line 14 expediently extends along the bottom of the algae breeding basin so that the CCh runs through Boreholes in this line are evenly distributed in the algae medium in the algae reproduction basin can distribute.

In the container 8 there is also a heat exchanger within the space filled with the floating dung to be decomposed 15 arranged, in which the heat generated by the decomposition of the manure is transferred to a heat transfer medium, for example water, is transferred. In or on the algae breeding basin is a second one, with the first heat exchanger 15 is arranged via a line pair 16 coupled heat exchanger 17, which the Liquid in the algae reproduction tank on an optimal level for the reproduction of the respective type of algae Temperature. The heat cycle is controlled via a <> 5 in the algae reproduction tank brought thermostats 18. The thermostat 18 is used to control a three-way valve 19 by depending on the temperature in the algae reproduction basin, the heat transfer from the container 8 to the algae reproduction basin 12 or to a bypass 20 is controlled.

So that even in the cold season there is sufficient heat transport from the container 8 to the algae multiplication basin 12 is guaranteed, the container 8 and the algae multiplication basin 12 are expedient thermally insulated. This also ensures that there is a sufficiently high in the container 8 Can adjust the temperature, since the activity of the bacteria is highest at temperatures of about bO to 70 ° is, which at the same time has the consequence that the decomposition process is most favorable at these temperatures runs.

Algae strains are located in the liquid algae medium in the algae multiplication basin 12, with Green algae of the genus Chlorella and Scenedesmus have proven particularly suitable as they are particularly are resistant to the local climatic conditions. The algae multiply with ingestion a large part of the substances contained in the processed alluvial dung, and in particular of the minerals, whereby the additional supply of CO: leads to a considerably increased increase. In addition, lighting devices in the lid the algae reproduction basin should be provided in order to provide sufficient light on days when the light intensity is insufficient To be able to make lighting. Under normal circumstances it will be sufficient if that Algae reproduction basin is open at the top or covered with a translucent layer. The operation of the algae reproduction basin 12 can be done continuously if the basin is so large that there is sufficient residence time is guaranteed. Semi-continuous operation is recommended for smaller pools.

A centrifugation system (not shown) can be provided in connection with the algae multiplication basin in order to centrifuge any substances not absorbed by the algae from the algae medium. this is done by centrifuging off part of the water in the algae that does not contain the algae absorbed substances are dissolved. These substances are essentially potassium carbonates, Sulfates and phosphates. The composition of the substances not absorbed by the algae depends on the essentially depends on the type of manure - i.e. which animals the manure comes from and with which Feed these animals are fed - and on the degree of decomposition in the container 8.

Furthermore, by centrifuging off some of the water, it becomes suitable for use as feed brought about a desirable thickening of the algae droplets.

The algae drinker is then fed to the stable 1 by means of a pump 21 via a line 22 pumped and introduced there as high-quality additional feed into the feeding troughs 23.

example

Pig manure was diluted with 4 parts of water and a thermally well insulated Oxydaiionsbälcr fed. The diluted pig manure was there for three days with constant stirring at 0.5 v / v / m Air (volume of air per volume slurry per minute) is applied. To avoid excessive foaming of the manure To prevent this, a Cm to Cie-Alcan solution was occasionally added as an antifoam agent. It posed

a temperature of 65 ° C. Subsequent rehearsals showed that all pathogenic germs and worm eggs had been killed.

The oxidizing substrate was then placed in an algae reproduction tank geleitel where there was a chlorella sludge. The multiplication time of the algae was many days. The algae mass that had been added by the propagation was then combined with Liquid withdrawn without intermediate separation and used as fodder in the drinking trough.

For this purpose 2 sheets of drawings

Claims (6)

"· Claims: 1. A method for propagating algae as supplementary feed for livestock, where excrement is decomposed in the presence of oxygen and then fed to the algae, characterized in that the excrement used is floating manure which is heated ^{to 60 to 70 0 C by aerobic oxidation,} and that the generated thermal energy is used to control the temperature of the Aigenmediums. 2. The method according to claim 1, characterized in that that CO2 produced during the decomposition is fed to the algae in gaseous form. 3. Plant for performing the method according to claim 1 or 2, characterized in that in or on a container (8) for decomposing the Schwemmisies and in or on an algae multiplication basin (12) heat exchangers (15, 17) coupled to one another to form a heat circuit are arranged are, whereby to regulate the temperature in the algae reproduction tank and thus to control a thermostat (18) is provided for the flow of heat from the container to the algae reproduction tank is, and that the container is provided with thermal insulation. 4. Plant according to claim 3, characterized in that the algae multiplication basin (12) is thermally insulated is. 5. Plant according to claim 3 or 4, characterized in that the container (8) is covered and a line (14) for conveying the CO2 produced during the decomposition to the algae multiplication basin (12) is provided. 6. Plant according to one of claims 3 to 5, characterized in that the algae reproduction basin (12) a device for removing substances not absorbed by the algae from the algae trough is downstream.